Preparation, characterization, Moessbauer spectra, and electron spin

Carl J. Long , Mark Naylor , Charles Moreland , Jon Bordner , Robert D. Bereman. Phosphorus and Sulfur and the Related Elements 1988 39 (3-4), 221-233...
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Inorganic Chemistry, Vol. 15, No. 3, 1976 K. Nakamoto, J. Fujita, R. Condrate, and Y. Morimoto, J . Chem. Phys., 39, 423 (1963). K. A. Jensen, B. M. Dahl, P. H. Nielsen, and G. Borch, Acta Chem. Stand., 26, 2241 (1972). I. Ojima, T. Onishi, T. Iwanioto, N. Inamoto, and K. Tamaru, Inorg. Nucl. Chem. Lett., 6, 65 (1970). P. C. Healy and A. H. White, J. Chem. Soc., Dalton Trans., 1883 (1972). F. S. Ham, Phys. Reu. A , , 138, 1727 (1965); F. S. Ham in “Electron Paramagnetic Resonance”, bv S. Geschwind, Ed., Plenum Press, New

York, g.Y., 1972, Chapter i. R. D. Dowsing and J . F. Gibson, J . Chem. Phys., 50, 294 (1969); H. H. Wickman, M. P. Klein, and D. A. Shirley, ibid, 42, 2115 (1965); T . Castner, G. S. Newell, W. C. Holton, and C. P. Slichter,32, 668 (1960). (a) R. Scaringe and G. Kokoszka, J . Chem. Phys., 60, 40 (1974); (b) P. W. Anderson and P. R. Weiss, Reu. Mod. Phys., 25, 269 (1963).

Bereman, Good, et al. B. Bleaney and M. C. M. O’Brien, Proc. Phys. Soc., London, Sect. B, 69, 1205 (1956). N. S. Garifyanov, S. S . Kamenev, B. M. Kozyrev, and I. V. Ovichinnikov, Dokl. Akad. Nauk. S S S R , 177, 880 (1967). R. Rickards, C. E. Johnson, and H. A. 0.Hill, J . Chem. Phys., 53, 31 18

(1970). However, a private communicationwith Dr. H. A. 0 .Hill informed us that, in fact, their cobalt substrate was relatively copper free and gave no copper EPR signal. Moreover, Dr. Hill suggested, and we concur, that copper was probably present in the iron sample and that this probably led to their copperlike EPR signal. R. M. Golding, E. Sinn, and W. C. Tennant, J . Chem. Phys., 56, 5296 (1972). C. Flick and E. Gelerinter, Chem. Phys. Lett., 23, 422 (1973). J. H. Ammeter and J. D. Swalen, J . Chem. Phys., 57, 678 (1972).

Contribution from the Department of Chemistry, The State University of New York at Buffalo, Buffalo, New York 14214, and the University of New Orleans, Lakefront, New Orleans, Louisiana 70122

Preparation, Characterization, Mossbauer Spectra, and Electron Spin Resonance Spectra of Iron(I1) and Iron(II1) Complexes of the Dithiolate Cyclopentadienedithiocarboxylate ROBERT D. BEREMAN,*la MARY L. GOOD,*lb BARBARA J. KALBACHER,la and J O H N BUTTONElb

Receiued August 18, 1975

AIC506 17J

The preparation of tetraethylammonium salts of bis(cyclopentadienedithiocarboxalato)ferrate(II) and tris(cyc1opentadienedithiocarboxalato)ferrate(III) is reported. Both complexes exhibit high-spin behavior. The Mossbauer spectrum of the iron(I1) complex is characterized by IS = 0.69 mm/s (metallic iron reference) and A E g = 4.52 mm/s at 78 K. The large quadrupole splitting is rationalized by the apparent five-coordination at the Fe(I1) ion in the solid state. The observation of a temperature-independent magnetic moment in the iron(II1) complex allows the placement of the cyclopentadienedithiocarboxylate ligand in the spectrochemical series of dithiolate ligands. The Mossbauer spectrum of the iron(II1) complex is characterized by IS = 0.41 mm/s (broad singlet with r of 1.71 mm/s) at 78 K. The electron spin resonance spectrum of the iron(II1) complex exhibits g = 9.30,4.31, and 0.77, characteristic of a large zero-field splitting of the 6Ssp system.

Introduction The tremendous interest which has been generated in the study of iron-sulfur enzymatic systems2,3 makes the study of ironsulfur complexes of varying oxidation states and chemical environments of particular importance. While a large body of work exists on iron(II1) 1,a-dithiolene and 1,l-dithiolate complexes, the majority are low spin in nature. Iron(I1) complexes are known but their occurrence is rare.4 In particular, aliphatic and aromatic iron(I1) dithiolates are unknown.5 Our interest in the effect of the cyclopentadienedithiocarboxylate (cpdt2-) ligand coupled with the large accumulation of knowledge on iron dithiolate complexes prompted our investigation of Fe-cpdt2- systems so that comparisons could be made. Experimental Section Materials. Acetonitrile was repeatedly distilled from phosphorus pentoxide. Anhydrous FeBrz and FeCh were purchased from Research Organic-Inorganic Chemical Corp. Anhydrous (C2Hs)dNCI and (C2H5)4NBr were obtained from Aldrich Chemical Co. The disodium salt of cyclopentadienedithiocarboxylic acid, NazSzCCsH4, was prepared as previously reported.6 [(C~HS)~N]~F~(C~H~CS~)Z. Typically, 0.613 g of FeBrz was dissolved in anhydrous degassed acetonitrile. The resulting solution was frozen and both 1.555 g of NazSzCCsH4 and 1.138 g of (C2Hs)dNBr were added. The resulting mixture was allowed to thaw slowly while stirring. After the resulting brown solution had stirred for 2 h at room temperature, NaBr was removed by filtration. The filtrate was reduced in volume under vacuum and the bright red product was removed by further filtration. Anal. Calcd for [(CZHS)~N]ZF~(C~H~CSZ)~: C, 56.35; H, 8.1 1; N, 4.69. Found: C, 56.44, H, 8.03; N , 4.74.

[(C~HS)~N]~F~(CSH~CS~)~. This air-sensitive brown complex was prepared in the same manner as the iron(I1) complex above. Typical starting ratios were 0.7002 g of FeC13, 3.3233 g of Na2S2CC5H4, and 2.189 g of (CzH5)dNCI. Anal. Calcd for [(C2H5)4N]3Fe(CCS2)3: C, 58.16; H , 8.31; N, 4.85; S, 22.18. Found: C, 57.65; H, 8.44; N , 4.66; S, 21.53. Analysis. All analyses were carried out by Galbraith Laboratories, Inc., Knoxville, Tenn. Methods. Reactions, filtrations, transfers, etc. were carried out in as rigorously anhydrous (nitrogen) an atmosphere as could be maintained employing Schlenk-tube techniques.6 Both compounds of iron were very air sensitive and decomposed to a black material almost instantaneously when exposed to the atmosphere. Magnetic Susceptibility Determinations. Magnetic susceptibilities were carried out on solid samples using the Gouy method and Hg[Co(SCN)4] as a calibrant. Pascal’s constants were used to correct for diamagnetic contributions from the ligand, the cation, and the core electrons of the metal.’ Measurements made at other than ambient room temperature employed a Dewar assembly and liquid nitrogen-solvent slushes or liquid nitrogen as coolant. Spectroscopic Measurements. Mossbauer spectra were obtained using an Austin Science Associates, Inc., spectrometer equipped with a “fast data accumulation package” electronics system. A Nuclear Data Model 2200 multichannel analyzer was used for data collection and storage. Data were transmitted via a teletype terminal into a PDP-10 computer for data reduction. A least-squares fit, assuming Lorentzian line shapes, was performed for each spectrum. Velocity calibration was done by laser interferometry and all spectra were referenced to an iron foil standard with the midpoint of the iron spectrum assigned an isomer shift value of 0.00 mm/s. Samples run at room temperature and at 4.2 K had source and absorber at the same temperature. Samples run at Dry Ice-acetone and liquid nitrogen temperatures had the source at room temperature. No second-order Doppler correction was made in the data reported.

Inorganic Chemistry, VoZ.15, No. 3, 1976 619

Iron(I1) and -(III) Dithiolate Complexes

Table 11. Mossbauer Parameters for {[(C,H,),NCS, 1,Fe},

.

i,

Temp, K 300 100

IS, mm/s 1.02 1.16

a,,mm/s 4.01 4.16

Table 111. Mossbauer Data for [(C,H,),N],Fe(C,H,CS,), One-line fit

-'4

am

3 000

2 008

1 000

888

2 000

1000

3

4 888

888

MWSEC

Figure 1. Mossbauer spectrum of [(C,H,),N],Fe(C,H,CS,),. Inner doublet is due to an Fe(II1) decomposition product. Table I. Mossbauer Parameters of [(C,H5)4N],Fe(C,H,CS,), Inner peaks

Temp, K

IS, mm/s

295 78 4.2

0.34 i: 0.02 0.40 i 0.01 0.31 k 0.02

AE,, mm/s

Outer peaks IS, mm/s

1.09 i 0.01 0.62 1.20 i 0.01 0.69 1.27 i 0.02 0.59

0.01 k 0.01 f 0.01 f

Line width, mm/s

Two-line fit

a,

Temp,

IS, mm/s

295 195 78 4.2

0.41 0.98 0.41 0.52 0.41 1.13 0.42 0.59 0.41 1.71 0.47 0.5 1 Spectra magnetically split into six lines

IS, mm/s

"7s

position.8 A molecular orbital calculation gave the relative ordering dX2-y2 < dxZ < d p < dZ2 < dxy, which is also in agreement with the ordering expected for square-pyramidal geometry.10 A detailed study of another Fe(I1) system, bis(5,5,7,7,-

a,mm/s ,

12,12,14-hexamethyl-1,4,8,1l-tetraazocyclotetradeca1-

4.56 4.52 4.65

(14),7-dione)iron(II) perchlorate, yielded a Mossbauer spectrum with a quadrupole splitting of 4.0 mm/s.ll This system again contains pentacoordinate Fe(I1) in a squarepyramidal structure with the iron slightly out of the basal plane and the perchlorate ion in the apical position. While the optical spectrum of bis(thiosemicarbazide)iron(II) [A& = 4.65 s-1 (300 K)] has been rationalized in terms of a distorted octahedron,l3 the arguments presented for the structural assignment do not rigorously preclude a five-coordinate system. Unfortunately, the above examples not withstLnding the large quadrupole splitting value does not allow the unequivocal assignment of pentacoordination since the eight-coordinate 1,8-naphthyridine complex of Fe(I1) exhibits a A& value of 4.54 mm/s.l2 For high-spin iron(I1) systems, the isomer shift has been related to the nephelauxtic effect of the ligand to which the ion is coordinated.9 Since the nephelauxtic effect corresponds to the fractional reduction of the interelectronic repulsion parameters in a complex relative to those of the free ion, it can be related to the expansion of the valence orbitals in the complex. This expansion of the valence d orbitals in iron should result in decreased shielding of the s electrons and a corresponding increase in s-electron density at the nucleus. Thus the lower value for the isomer shift (concomitant with greater s-electron density at the iron nucleus) exhibited by the cyclopentadienedithiocarboxylatocomplex as compared to the value for the bis(N,N-diethyldithiocabamato)iron(II) is evidence of the greater electron-withdrawing ability of the cpdt2ligand. The brown, air-sensitive tetraethylammonium tris(cyc1opentadienedithiocarboxylato)ferrate(III) exhibits a roomtemperature magnetic moment of 5.93 BM which corresponds to the expected spin-only moment of high-spin d5 systems. The magnetic moment remains constant between 77 and 300 K. As anticipated, only peaks due to the ligand could be observed in the opt&al spectrum. The Mossbauer spectra for the Fe(II1) compound (Figure 2 and Table 111) are consistent with a high-spin, slightly distorted, octahedral system.14 A broadened, temperature-independent singlet is observed between 295 and 78 K. The spectrum is magnetically split into the usual symmetric six-line pattern at 4.2 K. This magnetic hyperfine is a result of slow-spin relaxation in the complex at low temperature and is commonly exhibited by high-spin Fe(II1) systems having large organic ligands.14 The small quadrupole splitting, exhibited as line broadening at temperatures above 78 K, is probably due to some small amount of mixing-in of the 6Ai and 2T2 states via the 4T1 state which causes the energy

i i i

0.02 0.02 0.01

Mossbauer samples were loaded into special plastic petri dish type holders (2.54 cm in diameter) which contained paraffin in one side. The powdered sample was poured evenly over the half without paraffin and the two sides were pressed together to give a sample mounted on a layer of wax. Typically, samples ranged from 100 to 400 mg. The iron(II1) complex was loaded in a glovebag. Due to its exteme sensitivity, the iron(I1) sample was prepared in a drybox. Even under these conditions there was some darkening of the iron(I1) compound. After loading, the sample containers were sealed with parafilm and placed in glass tubes which were evacuated for shipment. ESR spectra were obtained as before.6

Results and Discussion Tetraethylammonium bis(cyclpentadienedithi0carboxylato)ferrate(II) is an extremely air-sensitive red complex. Slight decomposition to yield a brown product occurred in all attempts to handle the compound using Schlenk techniques. Of the other reported iron(I1) dithiolate complexes, only the bis(N,N-diethyldithiocarbamato)iron(II) complex does not undergo autoxidation when iron(I1) salts are employed as the starting materials in the syntheses.518The cyclopentadienedithiocarboxylate complex exhibits a magnetic moment of 4.83 BM which is indicative of a high-spin iron(I1) system without spin-orbit interaction.7 A representative Mossbauer spectrum of the complex is shown in Figure 1 and the Mossbauer data are given in Table I. The parameters are seen to be temperatuEe independent. All samples of the complex prepared for Mossbauer spectroscopy showed four peaks. The outer two peaks have parameters which are consistent with high-spin iron(I1); the inner two peaks correspond to iron(III).g It was found that if insufficient care were taken in storing the Mossbauer sample or if the complex were exposed to air, the outer peaks disappeared and only the inner two lines remained. The inner lines are thus assigned to an iron(TI1) decomposition product since they did not change in appearance with extended atmospheric exposure. Although the isomer shift of the outer doublet in Figure 1 is typical of high-spin Fe(II), the quadrupole splitting of ca. 4.56 mm/s is unusually large. There are at least four other Fe(I1) systems reported to have such large quadrupole splitting parameters, two of which are reported to contain pentacoordinate Fe(II).lo-13 The dimeric unit N,N-diethyldithiocarbamatoiron(I1) has the Mossbauer parameters listed in Table 11.10 X-ray powder spectra have indicated that the iron(I1) dithiocarbamate system is square pyramidal with the sulfur of a second [(C2Hs)2NCS2]2Fe unit in the apical

Bereman, Good, et al.

620 Inorganic Chemistry, Vol. 15, No. 3, 1976

Table IV. Electron Spin Resonance Parameters for [(C,Hs),Nl ,Fe(CsH,CS,), g values

-_

In CH,CN (100 K) Polycrystalline sample at room temperature ,

I

.

9.30, 4.31,0.77 9.32,4.15

The 7-donor ability (presumable in-plane T donation) apparently overrides the u-donor ability and the out-of-plane 7-acceptor character of the cpdt2- ligand in the Fe(II1) system. The proposed capability of the cpdt2- ligand to serve as a good T donor is substantiated by the large in-plane covalency exhibited by the cyclopentadienedithiocarboxylate in the molybdenyl(V) system.18 In order to understand further the electronic character of the iron(II1) complex, an electron spin resonance study was undertaken. An obvious feature of the spectrum is an intense isotropic absorption at g = 4.3 observed both in the frozen solution and in a polycrystalline sample (Table IV). Some broadening of the spectrum is noted, apparently due to spin-spin interaction in the solid state. A gvalue of 4.3 has been observed in other iron(II1) systems which are of biological importance.19-21 This is characteristic of a high-spin d5 (6Ssp) state in which the zero-field splitting interaction is large. The Hamiltonian for a system which exhibits zero-field splitting may be written

x=gpH.s+s,'-'/3s(s+1)+X(S,2-Sy2)

rJr__T---T--. -4.06~2 - 3 00a

-z.00a

- '

ea0

,880

$.me

z.000

3.wa

4.a00

Plfl/SEC

Figure 2. hlossbauer spectrum of [(C,H,),N] ,Fe(C,H,CS,),:

Where X = 0 corresponds to the situation of axial distortion and X = 1 / 3 corresponds to the situation of greatest rhombic distortion, Zero-field splitting gives rise to three Kramers doublets of the form =ai~rt5/2)

+ b i i ~ y z+)

A, 295 K; B, 195 K; C, 78 K.

$ik

levels to split and repel each other as a result of a small reduction from cubic symmetry. The observation of high-spin behavior for the FeIII-cpdtzcomplex allows the placement of the cyclopentadienedithiocarboxylate ligand in the spectrochemical series of other dithiolate ligands. For the 1,l-dithiolates of iron(III), the spectrochemicalseries is15-17 dtp- < dtc- < dtx- < dtb- < dta-, where dtp- = dithiophosphate, (R0)2PSS-; dtc- = dithiocarbamate, R2NCSS-; dtx- = dithioxanthate, ROCSS-; dtb= dithiobenzoate, C~HSCSS-;dta- = dithiophenylacetate, C6&CH2CSS-. The dithiophosphate complex of iron(II1) exhibits high-spin behavior while the N,N-diethyldithiocarbamate complex is an intermediate spin state, that is, exhibits a (high-spin)-(low-spin) equilibrium.15$16The other dithiolate ligands when complexed to iron(II1) all induce low-spin states. Thus, the high-spin nature of the iron(II1) complex of the cyclopentadienedithiocarboxylate ligand places the ligand with the dithiophosphate ligand in the spectrochemical series of dithiolate ligands. The dinegative 1,l-dithiolate isomaleonitriledithiolate (imnt) has been reported to also form a tris high-spin iron(II1) complex.5 This ligand exhibits electronic properties similar to those for the cdpt2- system.6 In fact, in all three of the ligands which are known to produce high-spin complexes (cpdt2-, dtp-, and imnt2-) the negative charge is localized on the sulfur donor atoms. In the dtp- case, the resonance form having a positively charged phosphorus and each sulfur negatively charged is expected to make a major contribution to the electronic structure of the ligand.16 All of these ligands M 7 donors than the corresponding moare better L nonegative l ,1-dithiolates. Thus, the splittings between the d orbitals in dtp-, imnt2; and cpdt2- are decreased relative to the other intermediates or low-spin dithiolate complexes.

Wickman et al.19 have plotted geff vs. E/D (or A) for the three doublets (Dserves as a measure of the axial distortion). They observed for the iron(II1) enzyme, ferrichrome A, a broad band of approximately 200 G at g = 4.3 for the transition of the middle doublet. They attributed the breadth of the peak to incomplete resolution of gx, gy, and gz for a X value less than 1f 3. A best fit was obtained for X = 0.25. Since our spectrum exhibits a narrower line of approximately 100 G, X is tentatively assigned as 1/3. Use of Wickman's plots dictates that the lower doublet transitions should occur at g equal to 9.6,0.8, and 0.6. Closer inspections of both the polycrystalline and frozen-solution spectra show a broad peak at low field centered at about 9.3 and one other absorption at high field with a g value of 0.76. No other transitions were observed at temperatures as low as -160 "C. For a geffvalue of 4.3, it is impossible to establish the sign of D as either positive or negative on the basis of the values of the g tensor for the lower doublet, since, for X = 1/3, the upper and lower doublets show transitions at the same positions. Furthermore, on the basis of the data presented here, it is impossible to separate the.value of D from E. In summary, the magnetic, Mossbauer and ESR parameters are all indicative of a high-spin, slightly distorted octahedral structure for the tris(cyclopentadienedithiocarboxy1ato)ferrate(II1) ion. No evidence of any (high-spin)-(low-spin) interconversion is obtained. Acknowledgment. R.D.B. wishes to acknowledge the partial support of the Petroleum Research Fund, administered by the American Chemical Society, and the Institutitional Funds of the Faculty of Natural Science and Mathematics of SUNY/Buffalo. M.L.G. wishes to acknowledge the partial support of NSF Grant No. GP-38054X. B.J.K. acknowledges a Henry Woodburn Fellowship during 1973-1974. R.D.B.

-

ci~i3/2)

EPR of CrIII Cbknblexes

Inorganic Chemistry, Vol. 15, No. 3, I976 621

gratefully acknowledges support from a Camille and Henry Dreyfus Foundation Fellowship, 1974-1979. Registry No. [(C2Hs)4N]2Fe(C5H4CS2)2, 57918-76-0; [(CzH s ) ~ N ] ~ F ~ ( C ~ H57918-78-2. ~CS~)~,

References and Notes (1) (a) The State University of New York at Buffalo. (b) University of New Orleans. (2) J. Herriott, L. C. Sieker, L. H. Jensen, and W. Lovenberg, J . Mol. Biol., 50, 391 (1970). (3) W. R. Dunham, G. Palmer, R. Sands, and A. Bearden, Biochem. Biophys. Acta, 253, 373 (1971). (4) J. A. McCleverty, Prog. Inorg. Chem., 10,49 (1968). (5) D.Coucouvanis, Prog. Inorg. Chem., 11, 294 (1970). (6) B. J. Kalbacher and R. D. Bereman, Inorg. Chem., 12, 2997 (1973). (7) B. N. Figgis and J. Lewis, “Modern Coordination Chemistry”, J. Lewis and R. G. Wilkins, Ed., Interscience, New York, N.Y., 1960,p 403.

(8) J. P.Fackler and D. G. Holah, Inorg. Nucl. Chem. Lett., 2, 251 (1966). (9) N. E. Erickson, Adu. Chem. Sei-., No. 68 (1967). (10) J. L.K.F. de Vries, C. P. Keijzers, and E. de Boer, Inorg. Chem., 11, 1343 (1972). (11) W. M. Reiff, Inorg. Chem., 13, 239 (1974). (12) E. Konig, G. Ritter, E. Linder, and J. P. Lorenz, Chem. Phys. Lett., 13, 70 (1972). (13) M.J. M. Campbell, Chem. Phys. Lett,., 15, 53 (1972). (14) N. N. Greenwood and T. C. Gibb, “Mossbauer Spectroscopy”, Barnes and Noble, Inc., London, 1971. (15) E. Cervone, F. D. Camassei, M. L. Luciani, and C. Furlani, J . Inorg. Nucl. Chem., 31, 1101 (1969). (16) C. J. Jorgenson, J . Inorg. Nucl. Chem., 24, 1571 (1962). (17) C. Furlani and M. L. Luciani, Inorg. Chem., 7 , 1586 (1968). (18) B. J. Kalbacher and R. D. Bereman, Inorg. Chem., 14, 1417 (1975). (19) H. H.Wickman, M. P. Klein, and D. A. Shirley, J . Chem. Phys., 42, 2113 (1965). (20) R. D. Dowsing and, J. F. Gibson, J . Chem. Phys., 50, 294 (1969). (21) R. Aasa, B. Malmstrom, P. Saltman, and T. Vanngard, Biochim. Biophys. Acta, 75, 203 (1963).

Contribution from the Department of General Chemistry, Molecular Spectroscopy Group, State University, Utrecht, The Netherlands

Electron Paramagnetic Resonance of Chromium(II1) Complexes of the Type cis-[Cr(2,2’-bpy)2XY]Z,cis-[Cr(l,lO-phen)2XY]Z, and cis-[Cr(ox)2XY]Z in Frozen Solutions and Powders W. T. M . ANDRIESSEN* and M. P. GROENEWEGE Received May 12, 1975

AIC503327

Frozen-solution spectra on X band as well as on Q band have been recorded for three series of Cr(II1) complexes of the type cis-[Cr(bpy)zXY]Z, cis- [Cr(phen)2XY]Z, and cis-[Cr(ox)zXY]Z, where XY is H20-H20, HzO-OH-, CI--Cl-, bpy, phen, ox, en, or acac. For some complexes the Cr-doped powder spectra of the corresponding Co(II1) complexes have been recorded. The D values of the three series exhibited correlations with the ligand field strengths of the XY ligands. The rhombic distortions of the complexes varied from 0.05 to 0.33 D.

Introduction

This investigation was undertaken in order to provide data about the paramagnetic behavior of cis Cr(II1) complexes and to correlate these data with parameters from the visible and ultraviolet spectra. Until now little work has been done on the EPR spectral of cis complexes. On the other hand, various series of trans Cr(II1) compounds2-4 have been investigated. In the case of trans complexes it has become clear that for some series3 the zero-field parameter D depends mainly on the difference of the ligand field strengths of the two substituting ligands on the one hand and the nonsubstituted ligands on the other hand. For other series234 the correlations between D and the ligand field strengths are much less convincing. It is assumed that for the most part this is due to the position of the Z principal axis in the complex. In the first case this axis is situated perpendicular to the plane of the nonsubstituted ligands and in the latter case it lies in the plane. For cis Cr(II1) complexes as studied in the present investigation, it can be expected that the behavior of the zero-field splitting D will reflect the cis substitution with respect to the ligand field strength, but to a smaller degree than in the case of purely tetragonal complexes because the Z axis is not situated in the plane of the XY ligands. Though these cis complexes are not strictly trigonal, they will be treated as such and in this paper will be described as trigonal in order to distinguish them from tetragonal complexes.36 Experimental Section Preparation of Complexes. Most chromium and all cobalt complexes were prepared by established methods-9 The complexes were characterized by means of ir spectroscopy.W The mixed complex with acetylacetonate, potassium acetylacetonatobis(oxa1ato)chro-

mate(II1) dihydrate, was prepared as follows. A 7.2-g sample of cisor trans-K2[Cr(ox)2H20(OH)]10 in 30 ml of 15% ethanol-water solution was boiled for 15 min with the stoichiometric amount of acetylacetone (2 ml). The green solution turned blue. With BaClz in excess, Ba[Cr(acac)(ox)2].2H20 was precipitated. This compound was treated with the calculated amount of KzS04 in about 10 ml of H20. To settle out the BaS04, the reaction mixture was allowed to stand for 0.5 h on a water bath. The filtrate was cooled to obtain blue-violet crystals of the K salt. Anal. Calcd for C9H70ioCrK2: C, 26.6; H , 1.7; 0, 39.5. Found: C, 25.9; H, 1.7; 0, 40.3. EPR Spectra. All EPR spectra were recorded on a Varian Model 4052 spectrometer at approximately -160 “C on X band as well as on Q band. The magnetic field strengths were measured with an AEG gaussmeter. The frequency was determined with a Takeda Riken counter, Model 5502A, equipped with a No. 5023 frequency converter. The more soluble compounds were dissolved in a mixture of water, methanol, and dimethylformamide (WMD) of composition 1:8:1. Less soluble compounds were measured in a mixture of 3:4:3 composition by volume.4 The pH dependence of the aqua complexes was first established with aqueous solutions of various pH values, frozen in a Sephadex matrix12 and then compared with the EPR spectra of a 6:2:2 W M D solution with the same pH. It appeared that there were only small differences between the two series, so for analyzing the data W M D frozen solutions were used. The EPR spectrum of cis-[Cr(ox)2HzO(OH)]2- was recorded in a buffered 6:2:2 W M D solution34 at p H 8.6, while those of cis-[Cr(bpy)zH20(OH)]2+ and cis-[Cr(phen)2HzO(OH)]2+ were both recorded6 at pH 4 7. The powders were prepared from aqueous solutions of the analogous Co(II1) compounds to which 1-2% of the Cr complex was added. The solutions were allowed to crystallize in darkness in order to prevent decomposition.9 For the measurements only well-shaped crystallites were used. As for K[Cr(ox)zphen], the analogous Co compound could not be prepared; this complex was added to the double complex9 [Co(ox)zphen][Co(ox)(phen)2].3HzO. The EPR spectrum showed